Oxidative metabolites accelerate Alzheimer's amyloidogenesis by a two-step mechanism, eliminating the requirement for nucleation

The process of amyloid formation by the amyloid beta peptide (Abeta), i.e., the misassembly of Abetapeptides into soluble quaternary structures and, ultimately, amyloid fibrils, appears to be at the center of Alzheimer's disease (AD) pathology. We have shown that abnormal oxidative metabolites, including cholesterol-derived aldehydes, modify Abeta and accelerate the early stages of amyloidogenesis (the formation of spherical aggregates). This process, which we have termed metabolite-initiated protein misfolding, could explain why hypercholesterolemia and inflammation are risk factors for sporadic AD. Herein, the mechanism by which cholesterol metabolites hasten Abeta 1-40 amyloidogenesis is explored, revealing a process that has at least two steps. In the first step, metabolites modify Abeta peptides by Schiff base formation. The Abeta-metabolite adducts form spherical aggregates by a downhill polymerization that does not require a nucleation step, dramatically accelerating Abeta aggregation. In agitated samples, a second step occurs in which fibrillar aggregates form, a step also accelerated by cholesterol metabolites. However, the metabolites do not affect the rate of fibril growth in seeded aggregation assays; their role appears to be in initiating amyloidogenesis by lowering the critical concentration for aggregation into the nanomolar range. Small molecules that block Schiff base formation inhibit the metabolite effect, demonstrating the importance of the covalent adduct. Metabolite-initiated amyloidogenesis offers an explanation for how Abeta aggregation could occur at physiological nanomolar concentrations.     

CLAC binds to aggregated Abeta and Abeta fragments, and attenuates fibril elongation

Deposition of amyloid beta-peptide (Abeta) into amyloid plaques is one of the invariant neuropathological features of Alzheimer's disease. Proteins that codeposit with Abeta are potentially important for the pathogenesis, and a recently discovered plaque-associated protein is the collagenous Alzheimer amyloid plaque component (CLAC). In this study, we investigated the molecular interactions between Abeta aggregates and CLAC using surface plasmon resonance spectroscopy and a solid-phase binding immunoassay. We found that CLAC binds to Abeta with high affinity, that the central region of Abeta is necessary and sufficient for CLAC interaction, and that the aggregation state of Abeta as well as the presence of negatively charged residues is important. We also show that this binding results in a reduced rate of fibril elongation. Taken together, we suggest that CLAC becomes involved at an intermediate stage in the pathogenesis by binding to Abeta fibrils, including fibrils formed from peptides with truncated N- or C-termini, and thereby slows their growth.     

An atomic model for the pleated beta-sheet structure of Abeta amyloid protofilaments.

Synchrotron x-ray studies on amyloid fibrils have suggested that the stacked pleated beta-sheets are twisted so that a repeating unit of 24 beta-strands forms a helical turn around the fibril axis (. J. Mol. Biol. 273:729-739). Based on this morphological study, we have constructed an atomic model for the twisted pleated beta-sheet of human Abeta amyloid protofilament. In the model, 48 monomers of Abeta 12-42 stack (four per layer) to form a helical turn of beta-sheet. Each monomer is in an antiparallel beta-sheet conformation with a turn located at residues 25-28. Residues 17-21 and 31-36 form a hydrophobic core along the fibril axis. The hydrophobic core should play a critical role in initializing Abeta aggregation and in stabilizing the aggregates. The model was tested using molecular dynamics simulations in explicit aqueous solution, with the particle mesh Ewald (PME) method employed to accommodate long-range electrostatic forces. Based on the molecular dynamics simulations, we hypothesize that an isolated protofilament, if it exists, may not be twisted, as it appears to be when in the fibril environment. The twisted nature of the protofilaments in amyloid fibrils is likely the result of stabilizing packing interactions of the protofilaments. The model also provides a binding mode for Congo red on Abeta amyloid fibrils. The model may be useful for the design of Abeta aggregation inhibitors.     

Inclusion bodies: specificity in their aggregation process and amyloid-like structure

The accumulation of aggregated protein in the cell is associated with the pathology of many diseases and constitutes a major concern in protein production. Intracellular aggregates have been traditionally regarded as nonspecific associations of misfolded polypeptides. This view is challenged by studies demonstrating that, in vitro, aggregation often involves specific interactions. However, little is known about the specificity of in vivo protein deposition. Here, we investigate the degree of in vivo co-aggregation between two self-aggregating proteins, Abeta42 amyloid peptide and foot-and-mouth disease virus VP1 capsid protein, in prokaryotic cells. In addition, the ultrastructure of intracellular aggregates is explored to decipher whether amyloid fibrils and intracellular protein inclusions share structural properties. The data indicate that in vivo protein aggregation exhibits a remarkable specificity that depends on the establishment of selective interactions and results in the formation of oligomeric and fibrillar structures displaying amyloid-like properties. These features allow prokaryotic Abeta42 intracellular aggregates to act as effective seeds in the formation of Abeta42 amyloid fibrils. Overall, our results suggest that conserved mechanisms underlie protein aggregation in different organisms. They also have important implications for biotechnological and biomedical applications of recombinant polypeptides.     

Surface structure of amyloid-beta fibrils contributes to cytotoxicity

Amyloid beta (Abeta) toxicity has been hypothesized to initiate the pathogenesis of Alzheimer's disease (AD). The characteristic fibrillar morphology of Abeta-aggregates, that constitute the main components of senile plaque, has long been considered to account for the neurotoxicity. But recent reports argue against a primary role for mature fibrils in AD pathogenesis because of the lack of a robust correlation between the severity of neurological impairment and the extent of amyloid deposition. Toxicity from the soluble prefibrillar intermediate entity of aggregates often called oligomer has recently proposed a plausible explanation for this inconsistency. An alternative explanation is based on the observation that certain amyloid fibril morphologies are more toxic than others, indicating that not all amyloid fibrils are equally toxic. Here, we report that it is not only the beta-sheeted fibrillar structure but also the surface physicochemical composition that affects the toxicity of Abeta fibrils. For the first time, colloidal gold was used to visualize by electron microscopy positive-charge clusters on Abeta fibrils. Chemical modifications as well as point-mutated Abeta synthesis techniques were applied to change the surface structures of Abeta and to show how local structure affects surface properties that are responsible for electrostatic and hydrophobic interactions with cells. We also report that covering the surface of Abeta fibers with myelin basic protein, which has surface properties contrary to those of Abeta, suppresses Abeta toxicity. On the basis of these results, we propose that the surface structure of Abeta fibrils plays an important role in Abeta toxicity.     

Neurotoxicity of acetylcholinesterase amyloid beta-peptide aggregates is dependent on the type of Abeta peptide and the AChE concentration present in the complexes.

Alzheimer's disease (AD) is a neurodegenerative disorder whose hallmark is the presence of senile plaques and neurofibrillary tangles. Senile plaques are mainly composed of amyloid beta-peptide (Abeta) fibrils and several proteins including acetylcholinesterase (AChE). AChE has been previously shown to stimulate the aggregation of Abeta1-40 into amyloid fibrils. In the present work, the neurotoxicity of different amyloid aggregates formed in the absence or presence of AChE was evaluated in rat pheochromocytoma PC12 cells. Stable AChE-Abeta complexes were found to be more toxic than those formed without the enzyme, for Abeta1-40 and Abeta1-42, but not for amyloid fibrils formed with AbetaVal18-Ala, a synthetic variant of the Abeta1-40 peptide. Of all the AChE-Abeta complexes tested the one containing the Abeta1-40 peptide was the most toxic. When increasing concentrations of AChE were used to aggregate the Abeta1-40 peptide, the neurotoxicity of the complexes increased as a function of the amount of enzyme bound to each complex. Our results show that AChE-Abeta1-40 aggregates are more toxic than those of AChE-Abeta1-42 and that the neurotoxicity depends on the amount of AChE bound to the complexes, suggesting that AChE may play a key role in the neurodegeneration observed in Alzheimer brain.     

Amyloid-beta(1-42) rapidly forms protofibrils and oligomers by distinct pathways in low concentrations of sodium dodecylsulfate

Alzheimer's disease (AD) is characterized by large numbers of senile plaques in the brain that consist of fibrillar aggregates of 40- and 42-residue amyloid-beta (Abeta) peptides. However, the degree of dementia in AD correlates better with the concentration of soluble Abeta species assayed biochemically than with histologically determined plaque counts, and several investigators now propose that soluble aggregates of Abeta are the neurotoxic agents that cause memory deficits and neuronal loss. These endogenous aggregates are minor components in brain extracts from AD patients and transgenic mice that express human Abeta, but several species have been detected by gel electrophoresis in sodium dodecylsulfate (SDS) and isolated by size exclusion chromatography (SEC). Endogenous Abeta aggregation is stimulated at cellular interfaces rich in lipid rafts, and anionic micelles that promote Abeta aggregation in vitro may be good models of these interfaces. We previously found that micelles formed in dilute SDS (2 mM) promote Abeta(1-40) fiber formation by supporting peptide interaction on the surface of a single micelle complex. In contrast, here we report that monomeric Abeta(1-42) undergoes an immediate conversion to a predominant beta-structured conformation in 2 mM SDS which does not proceed to amyloid fibrils. The conformational change is instead rapidly followed by the near quantitative conversion of the 4 kDa monomer SDS gel band to 8-14 kDa bands consistent with dimers through tetramers. Removal of SDS by dialysis gave a shift in the predominant SDS gel bands to 30-60 kDa. While these oligomers resemble the endogenous aggregates, they are less stable. In particular, they do not elute as discrete species on SEC, and they are completed disaggregated by boiling in 1% SDS. It appears that endogenous oligomeric Abeta aggregates are stabilized by undefined processes that have not yet been incorporated into in vitro Abeta aggregation procedures.     

Gerstmann-Sträussler-Scheinker disease amyloid protein polymerizes according to the "dock-and-lock" model

Prion protein (PrP) amyloid formation is a central feature of genetic and acquired prion diseases such as Gerstmann-Str?ussler-Scheinker disease (GSS) and variant Creutzfeldt-Jakob disease. The major component of GSS amyloid is a PrP fragment spanning residues approximately 82-146, which when synthesized as a peptide, readily forms fibrils featuring GSS amyloid. The present study employed surface plasmon resonance (SPR) to characterize the binding events underlying PrP82-146 oligomerization at the first stages of fibrillization, according to evidence suggesting a pathogenic role of prefibrillar oligomers rather than mature amyloid fibrils. We followed in real time the binding reactions occurring during short term (seconds) addition of PrP82-146 small oligomers (1-5-mers, flowing species) onto soluble prefibrillar PrP82-146 aggregates immobilized on the sensor surface. SPR data confirmed very efficient aggregation/elongation, consistent with the hypothesis of nucleation-dependent polymerization process. Much lower binding was observed when PrP82-146 flowed onto the scrambled sequence of PrP82-146 or onto prefibrillar Abeta42 aggregates. As previously found with Abeta40, SPR data could be adequately fitted by equations modeling the "dock-and-lock" mechanism, in which the "locking" step is due to sequential conformational changes, each increasing the affinity of the monomer for the fibril until a condition of irreversible binding is reached. However, these conformational changes (i.e. the locking steps) appear to be faster and easier with PrP82-146 than with Abeta40. Such differences suggest that PrP82-146 has a greater propensity to polymerize and greater stability of the aggregates.     

Urea modulation of beta-amyloid fibril growth: experimental studies and kinetic models

Aggregation of beta-amyloid (Abeta) into fibrillar deposits is widely believed to initiate a cascade of adverse biological responses associated with Alzheimer's disease. Although it was once assumed that the mature fibril was the toxic form of Abeta, recent evidence supports the hypothesis that Abeta oligomers, intermediates in the fibrillogenic pathway, are the dominant toxic species. In this work we used urea to reduce the driving force for Abeta aggregation, in an effort to isolate stable intermediate species. The effect of urea on secondary structure, size distribution, aggregation kinetics, and aggregate morphology was examined. With increasing urea concentration, beta-sheet content and the fraction of aggregated peptide decreased, the average size of aggregates was reduced, and the morphology of aggregates changed from linear to a globular/linear mixture and then to globular. The data were analyzed using a previously published model of Abeta aggregation kinetics. The model and data were consistent with the hypothesis that the globular aggregates were intermediates in the amyloidogenesis pathway rather than alternatively aggregated species. Increasing the urea concentration from 0.4 M to 2 M decreased the rate of filament initiation the most; between 2 M and 4 M urea the largest change was in partitioning between the nonamyloid and amyloid pathways, and between 4 M and 6 M urea, the most significant change was a reduction in the rate of filament elongation.     

Rapid assembly of amyloid-beta peptide at a liquid/liquid interface produces unstable beta-sheet fibers

Accumulation of aggregated amyloid-beta peptide (Abeta) in the brain is a pathological hallmark of Alzheimer's disease (AD). In vitro studies indicate that the 40- to 42-residue Abeta peptide in solution will undergo self-assembly leading to the transient appearance of soluble protofibrils and ultimately to insoluble fibrils. The Abeta peptide is amphiphilic and accumulates preferentially at a hydrophilic/hydrophobic interface. Solid surfaces and air-water interfaces have been shown previously to promote Abeta aggregation, but detailed characterization of these aggregates has not been presented. In this study Abeta(1-40) introduced to aqueous buffer in a two-phase system with chloroform aggregated 1-2 orders of magnitude more rapidly than Abeta in the buffer alone. The interface-induced aggregates were released into the aqueous phase and persisted for 24-72 h before settling as a visible precipitate at the interface. Thioflavin T fluorescence and circular dichroism analyses confirmed that the Abeta aggregates had a beta-sheet secondary structure. However, these aggregates were far less stable than Abeta(1-40) protofibrils prepared in buffer alone and disaggregated completely within 3 min on dilution. Atomic force microscopy revealed that the aggregates consisted of small globules 4-5 nm in height and long flexible fibers composed of these globules aligned roughly along a longitudinal axis, a morphology distinct from that of Abeta protofibrils prepared in buffer alone. The relative instability of the fibers was supported by fiber interruptions apparently introduced by brief washing of the AFM grids. To our knowledge, unstable aggregates of Abeta with beta-sheet structure and fibrous morphology have not been reported previously. Our results provide the clearest evidence yet that the intrinsic beta-sheet structure of an in vitro Abeta aggregate depends on the aggregation conditions and is reflected in the stability of the aggregate and the morphology observed by atomic force microscopy. Resolution of these structural differences at the molecular level may provide important clues to the further understanding of amyloid formation in vivo.     

Secondary structure and interfacial aggregation of amyloid-beta(1-40) on sodium dodecyl sulfate micelles

Alzheimer's disease (AD) is characterized by the presence of large numbers of fibrillar amyloid deposits in the form of senile plaques in the brain. The fibrils in senile plaques are composed of 40- and 42-residue amyloid-beta (Abeta) peptides. Several lines of evidence indicate that fibrillar Abeta and especially soluble Abeta aggregates are important in the pathogenesis of AD, and many laboratories have investigated soluble Abeta aggregates generated from monomeric Abeta in vitro. Of these in vitro aggregates, the best characterized are called protofibrils. They are composed of globules and short rods, show primarily beta-structure by circular dichroism (CD), enhance the fluorescence of bound thioflavin T, and readily seed the growth of long fibrils. However, one difficulty in correlating soluble Abeta aggregates formed in vitro with those in vivo is the high probability that cellular interfaces affect the aggregation rates and even the aggregate structures. Reports that focus on the features of interfaces that are important in Abeta aggregation have found that amphiphilic interactions and micellar-like Abeta structures may play a role. We previously described the formation of Abeta(1-40) aggregates at polar-nonpolar interfaces, including those generated at microdroplets formed in dilute hexafluoro-2-propanol (HFIP). Here we compared the Abeta(1-40) aggregates produced on sodium dodecyl sulfate (SDS) micelles, which may be a better model of biological membranes with phospholipids that have anionic headgroups. At both HFIP and SDS interfaces, changes in peptide secondary structure were observed by CD immediately when Abeta(1-40) was introduced. With HFIP, the change involved an increase in predominant beta-structure content and in fluorescence with thioflavin T, while with SDS, a partial alpha-helical conformation was adopted that gave no fluorescence. However, in both systems, initial amorphous clustered aggregates progressed to soluble fibers rich in beta-structure over a roughly 2 day period. Fiber formation was much faster than in the absence of an interface, presumably because of the close intermolecular proximity of peptides at the interfaces. While these fibers resembled protofibrils, they failed to seed the aggregation of Abeta(1-40) monomers effectively.     

Docosahexaenoic acid stabilizes soluble amyloid-beta protofibrils and sustains amyloid-beta-induced neurotoxicity in vitro

Enrichment of diet and culture media with the polyunsaturated fatty acid docosahexaenoic acid has been found to reduce the amyloid burden in mice and lower amyloid-beta (Abeta) levels in both mice and cultured cells. However, the direct interaction of polyunsaturated fatty acids, such as docosahexaenoic acid, with Abeta, and their effect on Abeta aggregation has not been explored in detail. Therefore, we have investigated the effect of docosahexaenoic acid, arachidonic acid and the saturated fatty acid arachidic acid on monomer oligomerization into protofibrils and protofibril fibrillization into fibrils in vitro, using size exclusion chromatography. The polyunsaturated fatty acids docosahexaenoic acid and arachidonic acid at micellar concentrations stabilized soluble Abeta42 wild-type protofibrils, thereby hindering their conversion to insoluble fibrils. As a consequence, docosahexaenoic acid sustained amyloid-beta-induced toxicity in PC12 cells over time, whereas Abeta without docosahexaenoic acid stabilization resulted in reduced toxicity, as Abeta formed fibrils. Arachidic acid had no effect on Abeta aggregation, and neither of the fatty acids had any protofibril-stabilizing effect on Abeta42 harboring the Arctic mutation (AbetaE22G). Consequently, AbetaArctic-induced toxicity could not be sustained using docosahexaenoic acid. These results provide new insights into the toxicity of different Abeta aggregates and how endogenous lipids can affect Abeta aggregation.     

Review: modulating factors in amyloid-beta fibril formation

Amyloid formation is a key pathological feature of Alzheimer's disease and is considered to be a major contributing factor to neurodegeneration and clinical dementia. Amyloid is found as both diffuse and senile plaques in the parenchyma of the brain and is composed primarily of the 40- to 42-residue amyloid-beta (Abeta) peptides. The characteristic amyloid fiber exhibits a high beta-sheet content and may be generated in vitro by the nucleation-dependent self-association of the Abeta peptide and an associated conformational transition from random to beta-conformation. Growth of the fibrils occurs by assembly of the Abeta seeds into intermediate protofibrils, which in turn self-associate to form mature fibers. This multistep process may be influenced at various stages by factors that either promote or inhibit Abeta fiber formation and aggregation. Identification of these factors and understanding the driving forces behind these interactions as well as the structural motifs necessary for these interactions will help to elucidate potential sites that may be targeted to prevent amyloid formation and its associated toxicity. This review will discuss some of the modulating factors that have been identified to date and their role in fibrillogenesis.     

pH-dependent amyloid and protofibril formation by the ABri peptide of familial British dementia

The ABri is a 34 residue peptide that is the major component of amyloid deposits in familial British dementia. In the amyloid deposits, the ABri peptide adopts aggregated beta-pleated sheet structures, similar to those formed by the Abeta peptide of Alzheimer's disease and other amyloid forming proteins. As a first step toward elucidating the molecular mechanisms of the beta-amyloidosis, we explored the ability of the environmental variables (pH and peptide concentration) to promote beta-sheet fibril structures for synthetic ABri peptides. The secondary structures and fibril morphology were characterized in parallel using circular dichroism, atomic force microscopy, negative stain electron microscopy, Congo red, and thioflavin-T fluorescence spectroscopic techniques. As seen with other amyloid proteins, the ABri fibrils had characteristic binding with Congo red and thioflavin-T, and the relative amounts of beta-sheet and amyloid fibril-like structures are influenced strongly by pH. In the acidic pH range 3.1-4.3, the ABri peptide adopts almost exclusively random structure and a predominantly monomeric aggregation state, on the basis of analytical ultracentrifugation measurements. At neutral pH, 7.1-7.3, the ABri peptide had limited solubility and produced spherical and amorphous aggregates with predominantly beta-sheet secondary structure, whereas at slightly acidic pH, 4.9, spherical aggregates, intermediate-sized protofibrils, and larger-sized mature amyloid fibrils were detected by atomic force microscopy. With aging at pH 4.9, the protofibrils underwent further association and eventually formed mature fibrils. The presence of small amounts of aggregated peptide material or seeds encourage fibril formation at neutral pH, suggesting that generation of such seeds in vivo could promote amyloid formation. At slightly basic pH, 9.0, scrambling of the Cys5-Cys22 disulfide bond occurred, which could lead to the formation of covalently linked aggregates. The presence of the protofibrils and the enhanced aggregation at slightly acidic pH is consistent with the behavior of other amyloid-forming proteins, which supports the premise that a common mechanism may be involved in protein misfolding and beta-amyloidosis.     

Role of aggregation conditions in structure, stability, and toxicity of intermediates in the Abeta fibril formation pathway

beta-amyloid peptide (Abeta) is one of the main protein components of senile plaques associated with Alzheimer's disease (AD). Abeta readily aggregates to forms fibrils and other aggregated species that have been shown to be toxic in a number of studies. In particular, soluble oligomeric forms are closely related to neurotoxicity. However, the relationship between neurotoxicity and the size of Abeta aggregates or oligomers is still under investigation. In this article, we show that different Abeta incubation conditions in vitro can affect the rate of Abeta fibril formation, the conformation and stability of intermediates in the aggregation pathway, and toxicity of aggregated species formed. When gently agitated, Abeta aggregates faster than Abeta prepared under quiescent conditions, forming fibrils. The morphology of fibrils formed at the end of aggregation with or without agitation, as observed in electron micrographs, is somewhat different. Interestingly, intermediates or oligomers formed during Abeta aggregation differ greatly under agitated and quiescent conditions. Unfolding studies in guanidine hydrochloride indicate that fibrils formed under quiescent conditions are more stable to unfolding in detergent than aggregation associated oligomers or Abeta fibrils formed with agitation. In addition, Abeta fibrils formed under quiescent conditions were less toxic to differentiated SH-SY5Y cells than the Abeta aggregation associated oligomers or fibrils formed with agitation. These results highlight differences between Abeta aggregation intermediates formed under different conditions and provide insight into the structure and stability of toxic Abeta oligomers.     

Effect of different salt ions on the propensity of aggregation and on the structure of Alzheimer's abeta(1-40) amyloid fibrils

The formation of amyloid fibrils and other polypeptide aggregates depends strongly on the physico-chemical environment. One such factor affecting aggregation is the presence and concentration of salt ions. We have examined the effects of salt ions on the aggregation propensity of Alzheimer's Abeta(1-40) peptide and on the structure of the dissolved and of the fibrillar peptide. All salts examined promote aggregation strongly. The most pronounced effect is seen within the cationic series, i.e. for MgCl2. Evaluation of different possible explanations suggests that Abeta(1-40) aggregation depends on direct interaction between ions and Abeta(1-40) peptide, and correlates with ion-induced changes of the surface tension. Salts have profound effects on the fibril structure. In the presence of salts, fibrils are associated with smaller diameters, narrower crossover distances and lower amide I maxima. Since Abeta(1-40) aggregation responds to salts in a manner unlike that for other polypeptides, such as glucagon, beta2-microglobulin or alpha-synuclein; these data argue that there is no fully uniform way in which salts affect aggregation of different polypeptide chains. These observations are important for understanding and predicting aggregation on the basis of simple physico-chemical properties.     

High hydrostatic pressure dissociates early aggregates of TTR105-115, but not the mature amyloid fibrils

A range of disorders such as Alzheimer's disease and type II diabetes have been linked to protein misfolding and aggregation. Transthyretin is an amyloidogenic protein which is involved in familial amyloid polyneuropathy, the most common form of systemic amyloid disease. A peptide fragment of this protein, TTR105-115, has been shown to form well-defined amyloid fibrils in vitro. In this study, the stability of amyloid fibrils towards high hydrostatic pressure has been investigated by Fourier transform infrared spectroscopy. Information on the morphology of the species exposed to high hydrostatic pressure was obtained by atomic force microscopy. The species formed early in the aggregation process were found to be dissociated by relatively low hydrostatic pressure (220 MPa), whereas mature fibrils are pressure insensitive up to 1.3 GPa. The pressure stability of the mature fibrils is consistent with a fibril structure in which there is an extensive hydrogen bond network in a tightly packed environment from which water is excluded. The fact that early aggregates can be dissociated by low pressure suggests, however, that hydrophobic and electrostatic interactions are the dominant factors stabilizing the species formed in the early stages of fibril formation.     

Identification of a mutant amyloid peptide that predominantly forms neurotoxic protofibrillar aggregates

The amyloid peptide (Abeta), derived from the proteolytic cleavage of the amyloid precursor protein (APP) by beta- and gamma-secretases, undergoes multistage assemblies to fibrillar depositions in the Alzheimer's brains. Abeta protofibrils were previously identified as an intermediate preceding insoluble fibrils. While characterizing a synthetic Abeta variant named EV40 that has mutations in the first two amino acids (D1E/A2V), we discerned unusual aggregation profiles of this variant. In comparison of the fibrillogenesis and cellular toxicity of EV40 to the wild-type Abeta peptide (Abeta40), we found that Abeta40 formed long fibrillar aggregates while EV40 formed only protofibrillar aggregates under the same in vitro incubation conditions. Cellular toxicity assays indicated that EV40 was slightly more toxic than Abeta40 to human neuroblastoma SHEP cells, rat primary cortical, and hippocampal neurons. Like Abeta40, the neurotoxicity of the protofibrillar EV40 could be partially attributed to apoptosis since multiple caspases such as caspase-9 were activated after SHEP cells were challenged with toxic concentrations of EV40. This suggested that apoptosis-induced neuronal loss might occur before extensive depositions of long amyloid fibrils in AD brains. This study has been the first to show that a mutated Abeta peptide formed only protofibrillar species and mutations of the amyloid peptide at the N-terminal side affect the dynamic amyloid fibrillogenesis. Thus, the identification of EV40 may lead to further understanding of the structural perturbation of Abeta to its fibrillation.     

Amyloid-beta protofibrils differ from amyloid-beta aggregates induced in dilute hexafluoroisopropanol in stability and morphology

The brains of Alzheimer's disease (AD) patients contain large numbers of amyloid plaques that are rich in fibrils composed of 40- and 42-residue amyloid-beta (Abeta) peptides. Several lines of evidence indicate that fibrillar Abeta and especially soluble Abeta aggregates are important in the etiology of AD. Recent reports also stress that amyloid aggregates are polymorphic and that a single polypeptide can fold into multiple amyloid conformations. Here we demonstrate that Abeta-(1-40) can form soluble aggregates with predominant beta-structures that differ in stability and morphology. One class of aggregates involved soluble Abeta protofibrils, prepared by vigorous overnight agitation of monomeric Abeta-(1-40) at low ionic strength. Dilution of these aggregation reactions induced disaggregation to monomers as measured by size exclusion chromatography. Protofibril concentrations monitored by thioflavin T fluorescence decreased in at least two kinetic phases, with initial disaggregation (rate constant approximately 1 h(-1)) followed by a much slower secondary phase. Incubation of the reactions without agitation resulted in less disaggregation at slower rates, indicating that the protofibrils became progressively more stable over time. In fact, protofibrils isolated by size exclusion chromatography were completely stable and gave no disaggregation. A second class of soluble Abeta aggregates was generated rapidly (<10 min) in buffered 2% hexafluoroisopropanol (HFIP). These aggregates showed increased thioflavin T fluorescence and were rich in beta-structure by circular dichroism. Electron microscopy and atomic force microscopy revealed initial globular clusters that progressed over several days to soluble fibrous aggregates. When diluted out of HFIP, these aggregates initially were very unstable and disaggregated completely within 2 min. However, their stability increased as they progressed to fibers. Relative to Abeta protofibrils, the HFIP-induced aggregates seeded elongation by Abeta monomer deposition very poorly. The techniques used to distinguish these two classes of soluble Abeta aggregates may be useful in characterizing Abeta aggregates formed in vivo.